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Network softwarehardware interaction a case study

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Network software/hardware interaction -- a case study. V. Karamcheti and A. A. ... A case study on the communication performance issues on the CM5 machine. Background ... – PowerPoint PPT presentation

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Title: Network softwarehardware interaction a case study


1
Network software/hardware interaction -- a case
study
  • V. Karamcheti and A. A. Chien, Software Overhead
    in Messaging layers Where does the time go? ACM
    ASPLOS-VI, 1994.
  • A case study on the communication performance
    issues on the CM5 machine.

2
Background
  • The network requirement for a typical high
    performance computing user
  • In-order message delivery
  • Reliable delivery
  • Error control
  • Flow control
  • Deadlock free
  • Where should these functions be realized?
  • Network hardware? Network systems? Or a
    hardware/systems/software approach?

3
Background
  • Where should these functions be realized?
  • How does the Internet realize these functions?
  • No deadlock issue
  • Reliability/flow control/in-order delivery are
    done at the TCP layer?
  • The network layer (IP) provides best effort
    service.
  • IP is done in the software as well.
  • Drawbacks
  • Too many layers of software
  • Users need to go through the OS to access the
    communication hardware (system calls can cause
    context switching).

4
Background
  • Where should these functions be realized?
  • High performance networking
  • Most functionality below the network layer are
    done by the hardware (or almost hardware)
  • This provide the APIs for network transactions
  • If there is miss-match between what the network
    provides and what users want, a software
    messaging layer is created to bridge the gaps.

5
Messaging Layer
  • Bridge between the hardware functionality and the
    user communication requirement
  • Typical network hardware features
  • Arbitrary delivery order (adaptive/multipath
    routing)
  • Finite buffering
  • Limited fault handling
  • Typical user communication requirement
  • In-order delivery
  • End-to-end flow control
  • Reliable transmission

6
Messaging Layer
7
Communication cost
  • Communication cost hardware cost software
    cost
  • Hardware message time msize/bandwidth
  • Software time
  • Buffer management
  • End-to-end flow control
  • Running protocols
  • Which one is dominating?
  • Depends on how much the software has to do.

8
What this study did
  • Analyzing the software cost in the CM5 machine.
  • Investigating what overhead can be reduced if the
    underlining network provide higher level of
    service.

9
CM-5 Network hardware
  • Send store the dest node number and data in the
    NI send buffer
  • Receive load from the NI receive buffer
  • NI status is queries by loading the control
    registers

10
CM-5 Network hardware
  • Out-of-order delivery (adaptive routing)
  • Nodes, NI, and the network have finite buffering
  • Error detection, but not error correction.
  • Fixed packet size of five 32-bit words

11
CM-5 active message layer (CMAM)
  • Active message
  • A message with a small amount of computation at
    the receiving end.
  • Each message contain an address of a user-level
    handler which is executed on message arrival with
    the message body as an argument.
  • The handler extract data from the network and
    integrate it into the ongoing computation.
  • CMAM vs Send/Recv
  • User direct access to network, no OS involve, the
    data go directly to the user space
  • CMAM can be considered as some kind of software
    RDMA.

12
Software overhead cost analysis
  • Consider implementation of 3 protocols
  • Single-packet delivery
  • Finite sequence, multi-packet delivery
  • Indefinite sequence, multi-packet delivery
  • Use instruction counts for measurement

13
Single-packet delivery
14
Finite sequence, multi-packet delivery
Packet transfer (4), buffer management (1, 2, 3,
5) Fault-tolerance (6), in-order delivery (extra
inst. In 4).
15
Indefinite sequence, multi-packet delivery
In order delivery sequence (store/send/read) Fa
ult-tolerance (1) and acks.
16
Message size 16 words
17
Message size 1024 words
18
What do we see in the study?
  • The mis-match between the user requirement and
    network functionality can introduce significant
    software overheads (50-70).

19
Messaging layer with high-level network feature
  • Given that CMAM is considered to be very
    efficient, there are 2 choices to reduce software
    overhead
  • Lower user requirement
  • Raise level of service provided by the network
  • Compressionless Routing (CR)
  • Order-preserving transmission
  • Deadlock freedom independent of packet acceptance
    guarantees
  • Fault-tolerant transmission at packet level

20
Single-packet delivery
  • Has the same cost as the previous CMAM case
  • However, it is guaranteed to be fault-free, no
    deadlock or buffer overflow

21
Finite sequence, multi-packet delivery
  • No buffer allocation messages
  • No overhead for in-order delivery
  • No end-to-end acks.

22
Indefinite sequence, multi-packet delivery
23
Message size 16 words
24
Message size 1024 words
25
Discussion
  • Larger packet sizes
  • Reduce overhead, especially for
    indefinite-sequence protocol
  • Improved network interfaces and DMA hardware
  • Network interface
  • only make basic cost faster, but not protocol
    cost in messaging layer
  • Make it more important for messaging layer to be
    effective
  • DMA
  • only reduce cost in moving large amounts of data

26
Discussion (Cont.)
  • Implication of network design
  • Improving routing performance may increase
    software cost, e.g. out-of-order delivery
  • Providing low level features to applications
  • Put burden on parallel software programmers
  • problematic

27
Conclusion
  • In the design of the communication system,
    holistic understanding must be achieved
  • Focusing on network hardware may not be
    sufficient. Software overhead is much larger than
    routing time.
  • It would be ideal for the network to directly
    provide high level services.
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